LOCKING(9FREEBSD) - man page online | system kernel interfaces

Kernel synchronization primitives.

Chapter

June 30, 2013

LOCKING(9) BSD Kernel Developer's Manual LOCKING(9)

NAME
locking — kernel synchronization primitives

DESCRIPTION
The FreeBSD kernel is written to run across multiple CPUs and as such provides several dif‐
ferent synchronization primitives to allow developers to safely access and manipulate many
data types.

Mutexes
Mutexes (also called "blocking mutexes") are the most commonly used synchronization primi‐
tive in the kernel. A thread acquires (locks) a mutex before accessing data shared with
other threads (including interrupt threads), and releases (unlocks) it afterwards. If the
mutex cannot be acquired, the thread requesting it will wait. Mutexes are adaptive by
default, meaning that if the owner of a contended mutex is currently running on another CPU,
then a thread attempting to acquire the mutex will spin rather than yielding the processor.
Mutexes fully support priority propagation.

See mutex(9) for details.

Spin Mutexes
Spin mutexes are a variation of basic mutexes; the main difference between the two is that
spin mutexes never block. Instead, they spin while waiting for the lock to be released. To
avoid deadlock, a thread that holds a spin mutex must never yield its CPU. Unlike ordinary
mutexes, spin mutexes disable interrupts when acquired. Since disabling interrupts can be
expensive, they are generally slower to acquire and release. Spin mutexes should be used
only when absolutely necessary, e.g. to protect data shared with interrupt filter code (see
bus_setup_intr(9) for details), or for scheduler internals.

Mutex Pools
With most synchronization primitives, such as mutexes, the programmer must provide memory to
hold the primitive. For example, a mutex may be embedded inside the structure it protects.
Mutex pools provide a preallocated set of mutexes to avoid this requirement. Note that
mutexes from a pool may only be used as leaf locks.

See mtx_pool(9) for details.

Reader/Writer Locks
Reader/writer locks allow shared access to protected data by multiple threads or exclusive
access by a single thread. The threads with shared access are known as readers since they
should only read the protected data. A thread with exclusive access is known as a writer
since it may modify protected data.

Reader/writer locks can be treated as mutexes (see above and mutex(9)) with shared/exclusive
semantics. Reader/writer locks support priority propagation like mutexes, but priority is
propagated only to an exclusive holder. This limitation comes from the fact that shared
owners are anonymous.

See rwlock(9) for details.

Read-Mostly Locks
Read-mostly locks are similar to reader/writer locks but optimized for very infrequent write
locking. Read-mostly locks implement full priority propagation by tracking shared owners
using a caller-supplied tracker data structure.

See rmlock(9) for details.

Sleepable Read-Mostly Locks
Sleepable read-mostly locks are a variation on read-mostly locks. Threads holding an exclu‐
sive lock may sleep, but threads holding a shared lock may not. Priority is propagated to
shared owners but not to exclusive owners.

Shared/exclusive locks
Shared/exclusive locks are similar to reader/writer locks; the main difference between them
is that shared/exclusive locks may be held during unbounded sleep. Acquiring a contested
shared/exclusive lock can perform an unbounded sleep. These locks do not support priority
propagation.

See sx(9) for details.

Lockmanager locks
Lockmanager locks are sleepable shared/exclusive locks used mostly in VFS(9) (as a vnode(9)
lock) and in the buffer cache (BUF_LOCK(9)). They have features other lock types do not
have such as sleep timeouts, blocking upgrades, writer starvation avoidance, draining, and
an interlock mutex, but this makes them complicated both to use and to implement; for this
reason, they should be avoided.

See lock(9) for details.

Counting semaphores
Counting semaphores provide a mechanism for synchronizing access to a pool of resources.
Unlike mutexes, semaphores do not have the concept of an owner, so they can be useful in
situations where one thread needs to acquire a resource, and another thread needs to release
it. They are largely deprecated.

See sema(9) for details.

Condition variables
Condition variables are used in conjunction with locks to wait for a condition to become
true. A thread must hold the associated lock before calling one of the cv_wait(), func‐
tions. When a thread waits on a condition, the lock is atomically released before the
thread yields the processor and reacquired before the function call returns. Condition
variables may be used with blocking mutexes, reader/writer locks, read-mostly locks, and
shared/exclusive locks.

See condvar(9) for details.

Sleep/Wakeup
The functions tsleep(), msleep(), msleep_spin(), pause(), wakeup(), and wakeup_one() also
handle event-based thread blocking. Unlike condition variables, arbitrary addresses may be
used as wait channels and a dedicated structure does not need to be allocated. However,
care must be taken to ensure that wait channel addresses are unique to an event. If a
thread must wait for an external event, it is put to sleep by tsleep(), msleep(),
msleep_spin(), or pause(). Threads may also wait using one of the locking primitive sleep
routines mtx_sleep(9), rw_sleep(9), or sx_sleep(9).

The parameter chan is an arbitrary address that uniquely identifies the event on which the
thread is being put to sleep. All threads sleeping on a single chan are woken up later by
wakeup() (often called from inside an interrupt routine) to indicate that the event the
thread was blocking on has occurred.

Several of the sleep functions including msleep(), msleep_spin(), and the locking primitive
sleep routines specify an additional lock parameter. The lock will be released before
sleeping and reacquired before the sleep routine returns. If priority includes the PDROP
flag, then the lock will not be reacquired before returning. The lock is used to ensure
that a condition can be checked atomically, and that the current thread can be suspended
without missing a change to the condition or an associated wakeup. In addition, all of the
sleep routines will fully drop the Giant mutex (even if recursed) while the thread is sus‐
pended and will reacquire the Giant mutex (restoring any recursion) before the function
returns.

The pause() function is a special sleep function that waits for a specified amount of time
to pass before the thread resumes execution. This sleep cannot be terminated early by
either an explicit wakeup() or a signal.

See sleep(9) for details.

Giant
Giant is a special mutex used to protect data structures that do not yet have their own
locks. Since it provides semantics akin to the old spl(9) interface, Giant has special
characteristics:

1. It is recursive.

2. Drivers can request that Giant be locked around them by not marking themselves MPSAFE.
Note that infrastructure to do this is slowly going away as non-MPSAFE drivers either
became properly locked or disappear.

3. Giant must be locked before other non-sleepable locks.

4. Giant is dropped during unbounded sleeps and reacquired after wakeup.

5. There are places in the kernel that drop Giant and pick it back up again. Sleep locks
will do this before sleeping. Parts of the network or VM code may do this as well.
This means that you cannot count on Giant keeping other code from running if your code
sleeps, even if you want it to.

INTERACTIONS
The primitives can interact and have a number of rules regarding how they can and can not be
combined. Many of these rules are checked by witness(4).

Bounded vs. Unbounded Sleep
In a bounded sleep (also referred to as “blocking”) the only resource needed to resume exe‐
cution of a thread is CPU time for the owner of a lock that the thread is waiting to
acquire. In an unbounded sleep (often referred to as simply “sleeping”) a thread waits for
an external event or for a condition to become true. In particular, a dependency chain of
threads in bounded sleeps should always make forward progress, since there is always CPU
time available. This requires that no thread in a bounded sleep is waiting for a lock held
by a thread in an unbounded sleep. To avoid priority inversions, a thread in a bounded
sleep lends its priority to the owner of the lock that it is waiting for.

The following primitives perform bounded sleeps: mutexes, reader/writer locks and read-
mostly locks.

The following primitives perform unbounded sleeps: sleepable read-mostly locks,
shared/exclusive locks, lockmanager locks, counting semaphores, condition variables, and
sleep/wakeup.

General Principles
· It is an error to do any operation that could result in yielding the processor while
holding a spin mutex.

· It is an error to do any operation that could result in unbounded sleep while holding
any primitive from the 'bounded sleep' group. For example, it is an error to try to
acquire a shared/exclusive lock while holding a mutex, or to try to allocate memory with
M_WAITOK while holding a reader/writer lock.

Note that the lock passed to one of the sleep() or cv_wait() functions is dropped before
the thread enters the unbounded sleep and does not violate this rule.

· It is an error to do any operation that could result in yielding of the processor when
running inside an interrupt filter.

· It is an error to do any operation that could result in unbounded sleep when running
inside an interrupt thread.

Interaction table
The following table shows what you can and can not do while holding one of the locking prim‐
itives discussed. Note that “sleep” includes sema_wait(), sema_timedwait(), any of the
cv_wait() functions, and any of the sleep() functions.

You want: spin mtx mutex/rw rmlock sleep rm sx/lk sleep
You have: -------- -------- ------ -------- ------ ------
spin mtx ok no no no no no-1
mutex/rw ok ok ok no no no-1
rmlock ok ok ok no no no-1
sleep rm ok ok ok ok-2 ok-2 ok-2/3
sx ok ok ok ok ok ok-3
lockmgr ok ok ok ok ok ok

*1 There are calls that atomically release this primitive when going to sleep and reacquire
it on wakeup (mtx_sleep(), rw_sleep(), msleep_spin(), etc.).

*2 These cases are only allowed while holding a write lock on a sleepable read-mostly lock.

*3 Though one can sleep while holding this lock, one can also use a sleep() function to
atomically release this primitive when going to sleep and reacquire it on wakeup.

Note that non-blocking try operations on locks are always permitted.

Context mode table
The next table shows what can be used in different contexts. At this time this is a rather
easy to remember table.

Context: spin mtx mutex/rw rmlock sleep rm sx/lk sleep
interrupt filter: ok no no no no no
interrupt thread: ok ok ok no no no
callout: ok ok ok no no no
system call: ok ok ok ok ok ok

SEE ALSO
witness(4), condvar(9), lock(9), mtx_pool(9), mutex(9), rmlock(9), rwlock(9), sema(9),
sleep(9), sx(9), BUS_SETUP_INTR(9), LOCK_PROFILING(9)

HISTORY
These functions appeared in BSD/OS 4.1 through FreeBSD 7.0.

BUGS
There are too many locking primitives to choose from.

BSD June 30, 2013 BSD

This manual	Reference	Other manuals
locking(9freebsd)	referred by	BUS_SETUP_INTR(9freebsd) \| bus_setup_intr(9freebsd) \| BUS_TEARDOWN_INTR(9freebsd) \| bus_teardown_intr(9freebsd) \| condvar(9freebsd) \| counter(9freebsd) \| counter_enter(9freebsd) \| counter_exit(9freebsd) \| counter_u64_add(9freebsd) \| counter_u64_add_protected(9freebsd) \| counter_u64_alloc(9freebsd) \| counter_u64_fetch(9freebsd) \| counter_u64_free(9freebsd) \| counter_u64_zero(9freebsd) \| cv_broadcast(9freebsd) \| cv_broadcastpri(9freebsd) \| cv_destroy(9freebsd) \| cv_init(9freebsd) \| cv_signal(9freebsd) \| cv_timedwait(9freebsd)
locking(9freebsd)	refer to	BUF_LOCK(9freebsd) \| condvar(9freebsd) \| lock(9freebsd) \| LOCK_PROFILING(9freebsd) \| mtx_pool(9freebsd) \| mtx_sleep(9freebsd) \| mutex(9freebsd) \| rmlock(9freebsd) \| rw_sleep(9freebsd) \| rwlock(9freebsd) \| sema(9freebsd) \| sleep(9freebsd) \| spl(9freebsd) \| sx(9freebsd) \| sx_sleep(9freebsd) \| VFS(9freebsd) \| vnode(9freebsd) \| witness(4freebsd)